Overconstrained character sums over finite abelian groups and decompositions of generalized bent, plateaued and landscape functions

Abstract

Generalized bent (gbent) functions from an n-variable Boolean space to Z2k are central in cryptography and sequence design. Instead of the usual binary decomposition, we introduce a 2-adic representation, for k= r, writing such functions as linear combinations of r component functions valued in Z2. We prove a general result on overconstrained character sums over finite abelian groups: under a common-argument hypothesis, sequences with two-level Fourier magnitude spectra must be extremely sparse, with a conditional extension to multi-level spectra. As an application, we derive consequences for generalized plateaued functions under suitable assumptions. We then show that if f:F2n2k is landscape, then under the 2-adic decomposition every function in a certain affine space over Z2 is again landscape with the same Walsh magnitudes. This gives an unconditional necessity result, with no structural assumptions on f, together with a complete characterization using only a small subset of these maps. For generalized bent and generalized plateaued functions, sufficiency is also obtained from linear combinations of lower components under natural assumptions; a counterexample shows these assumptions are essential. Our method reduces verification for landscape functions from 22k-1 checks to fewer than 2k-+1+1 conditions; for gbent functions this drops to a single basis function under the common-argument hypothesis, and for generalized plateaued functions, under additional assumptions, to 2k- checks. The 2-adic framework also preserves key properties, including duality and differential uniformity.